FIELD OF THE INVENTIONThe present invention generally relates to the field of batteries, in particular the present invention is directed to a novel battery having a collapsing vent system and overcharge protection.
BACKGROUND OF THE INVENTIONA persistent problem associated with the design of many types of sealed batteries is that under certain conditions the internal pressure generated by the electrochemical system contained within the sealed battery causes the battery to explode. This problem occurs in Lithium-ion cells as well as other battery types. The excessive internal pressure may be created by a chemical reaction or by the expansion of gases within the battery due to the presence of excessive heat. Alternatively, the battery may explode if there is a short circuit, if the battery is recharge too rapidly, or if the battery is recharged over an extended period of time. Therefore, it is important to have a safety mechanism for venting pressurized gases from the battery before a dangerous situation is encountered.
In some existing battery venting mechanisms, the vent is a separate part welded to one end of the cell. This type of system has flow limitations because it allows the battery to vent at only one end of the cell. Thus, when this type of battery has a fast thermal reaction, the vent opening can become clogged causing the cell enclosure to rupture and the cell components to burn.
A related problem is that existing batteries do not have an overcharge protection that is part of the battery's structure. Generally, the only overcharge protection is provided by an active device associated with the battery pack electronics. This lack of protection is a serious concern because a dangerous condition exists if a battery remains at an overcharged state or continues to charge during venting of excessive heat or pressurized gases. Furthermore, if a safety feature could prevent the pressure within the battery from reaching a level where venting is required, a dangerous situation would be avoided without the release of gases.
SUMMARY OF THE INVENTIONThe present invention is directed to eliminating the above problems associated with existing batteries, and more specifically battery venting mechanisms, through the use of a novel venting device and overcharge protection system. The present invention avoids the above problems associated with existing vent mechanisms by employing a number of novel features, which will be discussed here briefly, and in more detail below.
The battery casing has an inner tube that completely surrounds a hollow core and an outer tube that surrounds the inner tube. The inner tube is connected at both ends to two end plates. The inner tube, outer tube, and end plates form a sealed, hermetic annular space in which the battery components are held. The inner tube is designed to collapse into the hollow core when a pressure inside the annular space exceeds a predetermined collapsing pressure, and the welds connecting the inner tube to the end plates are designed to break when the pressure inside the annular space exceeds a predetermined breaking pressure.
In addition, the invention can take advantage of the fact that the inner tube is negatively charged by have a connecting member, which is electrically connected to the anode and thus positively charged, that extends into the hollow core. When the negatively charged inner tube collapses, it makes contact with the positively charged connecting member, to provide a short circuit for reducing the voltage of the battery.
BRIEF DESCRIPTION OF THE DRAWINGSThe advantages, nature and various additional features of the invention will appear more fully upon consideration of the illustrative embodiment of the invention which is schematically set forth in the drawings, in which:
FIG. 1 is a three dimensional view of the battery before the inner tube collapses;
FIG. 2 is a cross-sectional view of the battery before the inner tube collapses;
FIG. 3 is a three dimensional view of one end of the battery after the inner tube collapses;
FIG. 4 is a cross-sectional view of the battery before the inner tube collapses in which one of the end plates and the outer tube form a single part;
FIG. 5 is a cross-sectional view of the battery with the overcharge protection device before the inner tube collapses;
FIG. 6 is a three dimensional view of the battery with overcharge protection device before the inner tube collapses; and
FIG. 7 is a three dimensional view of the battery with overcharge protection device after the inner tube collapses.
DETAILED DESCRIPTION OF THE INVENTIONThe present invention will be explained in further detail by making reference to the accompanying drawings, which do not limit the scope of the invention in any way. Experiments have been performed with Lithium-ion cells, but the principles of this invention apply to other batteries that experience increased internal pressure.
Venting Device
Referring to the FIGS. 1 and 2, abattery casing100 houses an electrode assembly with ananode40, acathode42, and anelectrolytic separator44. The casing includes aninner tube10, and outer tube12, and twoend plates14,16 to create a sealed annular space.
In this embodiment, theinner tube10 is about 0.007 inches thick with an outside diameter of 0.625 inches, theouter tube18 is about 0.011 inches thick, and the end members are about 0.015 inches thick. Theouter tube18 andend plates14,16 and are made of 1008/1010 CRS steel, but they may be made of another suitable metal, and the inner tube is made of 304 SS steel.
Theinner tube10 is a ribless surface, which is not reinforced with grooves. Theend plates14,16 are attached to the ends of theinner tube10 andouter tube18. In this embodiment, theend plates14,16 are attached to theinner tube10 bywelds26 and to theouter tube18 by additional welds, but the invention is not limited in this respect.
Theanode40 andcathode42 are separated by theseparator44 and are spirally wound around theinner tube10. Theinner wall10 surrounds ahollow core20. Apositive terminal22 is connected to thecathode42 and extends through one of theend plates14, andnegative terminal24 is connected to theother end plate16. Theinner wall10 is electrically connected to the anode, and is there fore negatively charged.
In this embodiment, theend plates14,16 are semi-rigid structures formed by an inner cylinder, an outer cylinder, and a plate that extends between one of the ends of the outer cylinder and one of the ends of the inner cylinder, as shown in FIG.2.
When the pressure created by the charging of the battery increases to a first predetermined level within the annular space, a force within the annular space causes theinner tube10 to collapse and flatten into thehollow core20. FIG. 3 shows the battery after the inner tube has collapsed. Theinner wall10 is specifically designed so that it will collapse when it experiences a force caused by a pressure at a predetermined level. The ribless surface of the inner wall allows the tube to uniformly collapse rather than break at a predetermined pressure, as occurs in existing venting systems. In this embodiment, the force is about 140 psi. The collapsing of theinner tube10 increases the volume within the annular space. This increase in volume also increases the spacing between the anode electrode and cathode electrode, which reduces the current between the electrodes, and thus the power of the battery.
If the pressure within the annular space continues to increase even after the collapsing theinner tube10, the connection between theend plates14,16 and the inner tube will break at a predetermined higher pressure. In another embodiment, the pressure at which the connection between theend plates14,16 and theinner tube10 breaks can be the same pressure as the pressure where theinner tube10 collapses. In this embodiment, thewelds26 connecting theinner tube10 andend plates14,16 are designed to break at a pressure of about 250 to 300 psi. The breaking of thewelds26 at this pressure allows the battery to vent before reaching an unsafe pressure, such as 400 psi.
Referring to FIG. 4, in an alternative embodiment, theend plate16anear thenegative terminal24 and theouter tube18 form a single part. As in the previously described embodiments, theinner tube10 is welded to theend plate16aportion of the single part.
Overcharge Protection System
As shown in FIGS. 5 and 6, the invention can also have an overcharge protection system. This system includes aconductive member30 that is connected to thepositive terminal22. In this embodiment, theconductive member30 is welded to thepositive terminal22, but other means of conductivity coupling themember30 to the terminal22 so thatwire30 is to thepositive terminal16 may also be used. It extend through theend plate14, and then into thehollow core20.
In this embodiment, the conductive member is a 0.03 to 0.04 inch diameter tungsten wire, but other conductive materials such as 18 Gauge Nickel Chromium wire can be used. An insulatingmaterial32 is formed around the portion of the wire that extends from thepositive terminal22 to theend portion34 located within thehollow core20. The insulatingmaterial32 is shrink tubing in this embodiment, but any suitable insulating material may be used.
Theend portion36 is a larger diameter than theconductive member30. In this embodiment, the end portion is a 0.125 inch diameter copper cylinder that is press fit on thewire30. Anonconductive support34 is attached to thewire30 and located within thehollow core20.
Just like the embodiment described above, when the battery cell reaches an excessive voltage or the cell is exposed to excessive heat, the internal pressure within the annular portion of thebattery casing100 causes theinner tube10 to collapse and flatten into thehollow core20. FIG. 7 shows the battery after the inner tube has collapsed. This embodiment is designed so that the inner tube collapses at 4.75 Volts. When theinner tube10 collapses, it makes contact with thewire30, creating a short circuit between the positive terminal and the negatively chargedinner wall10. This short circuit reduces the excessive voltage, thus preventing electrolyte decomposition within the battery, which would result in an exothermic reaction and significantly increased pressures.
If the pressure within the annular space continues to increase, thewelds26 between theinner tube10 and theend plates14,16 will break in the same manner as described earlier with respect to the venting device.
The insulatingmaterial32 prevents theconductive member30 from touching thebattery casing100, which would prematurely create a short circuit. Thesupport portion34 prevents theconductive member30 from contacting theinner tube10 during shock or vibration. The largerdiameter end portion36 provides a larger surface for theinner tube10 to contact when it collapses. Theconductive member30 is designed so that its resistance value will support a current higher than the normal battery charge current, but is limited to avoid the overheating of thewire30 andbattery100.
Tests were conducted with a Lithium-ion cell. In these experiments, theinner wall10 collapsed due to excessive pressure when the cell was overcharged to 4.5 Volts and when the cell was exposed to a temperature of 150° C. for an extended period of time. It is of course understood that departures can be made from the preferred embodiment of the invention by those of ordinary skill in the art without departing from the spirit and scope of the invention that is limited only by the following claims, such as applying this invention to other types of batteries, using different conductive materials, or changing the sizes of the components.